Photo-luminescent visual elements, systems and methods

ABSTRACT

Disclosed are embodiments of photo-luminescent display systems and photo-luminescent visual elements creating eye-catching displays of visual advertising or marketing messages that are very effective at generating interest, engagement, and loyalty in the viewing public. Photo-luminescent pigment containing visual elements are illuminated by one or more remotely located emitters at a first wavelength that is outside the human visual spectrum. In response, the visual elements then radiate at one or more wavelengths within the human visual spectrum. Additional features control unwanted reflections and unwanted transmission of radiation at the first wavelength. Additional features control the uniformity of radiation of one or more wavelengths within the human visual spectrum.

CROSS REFERENCE TO RELATED APPLICATIONS

This non-provisional utility application is a continuation ofnon-provisional utility application Ser. No. 15/586,425, filed May 4,2017, entitled “Photo-luminescent Visual Elements, Systems and Methods”.Application Ser. No. 15/586,425 claimed the benefit of non-provisionalutility application Ser. No. 15/004,310, filed Jan. 22, 2016, entitled“Photo-luminescent Display System and Methods”. Application Ser. No.15/004,310 claimed the benefit of U.S. provisional Application No.62/107,573, filed Jan. 26, 2015, entitled “Photo-luminescent DisplaySystem”. Application Nos. 62/107,573, 15/004,310, and 15/586,425 areincorporated herein by reference.

STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT

Not Applicable.

DESCRIPTION OF ATTACHED APPENDIX

Not Applicable.

BACKGROUND

This invention relates generally to display devices and systems. Displaydevices and systems are found in a huge variety of contexts encounteredin daily life. When used for advertising and marketing, display systemsmay be used to make the public aware of various brands, products,services, and other items that are of particular interest to theirrespective advertisers and marketers. Appealing, interesting, andeye-catching displays of visual advertising or marketing messages can bevery effective at generating interest, engagement, and loyalty in theviewing public.

Photo-luminescent materials absorb electromagnetic (EM) energy from thesun or from man made light sources. The absorbed EM energy is thenradiated at a different wavelength. Some photo-luminescent materialsradiate absorbed EM energy quickly while others radiate the absorbed EMenergy slowly over the span of minutes to hours. Some photo-luminescentmaterials absorb EM energy at wavelengths outside the normal humanvisual spectrum and they radiate EM energy at wavelengths within thenormal human visual spectrum. Photo-luminescent materials can be used tocreate appealing, interesting, and eye-catching visual elements. Inconsideration of the foregoing points, it is clear that embodiments ofthe present disclosure confer numerous advantages and are thereforehighly desirable.

SUMMARY

The present disclosure is directed to systems and methods that createeye-catching displays of visual advertising or marketing messages.Embodiments of the present disclosure incorporate one or morephoto-luminescent visual elements which are activated by one or moreremotely located EM emitters to effectively stimulate photo-luminescentemissions of said photo-luminescent visual elements.

Exemplary Embodiment 1.0 {a Minimal System}

A display system according to an embodiment of the present disclosurecomprises: a photo-luminescent visual element receiving, from anemitter, an incoming electromagnetic radiation at a first wavelength andradiating an outgoing electromagnetic radiation at a second wavelength;said emitter producing said incoming electromagnetic radiation such thatat least a portion of said photo-luminescent visual element isilluminated; said first wavelength located outside of the visiblespectrum; said second wavelength located in the visible spectrum; andsaid emitter further characterized in that it is located remotely fromsaid photo-luminescent visual element.

Exemplary Embodiment 1.1 {1.0 Plus More than One Emitter}

In a related embodiment, a display system according to an embodiment ofthe present disclosure comprises: a photo-luminescent visual elementreceiving, from one or more emitters, incoming electromagnetic radiationat a first wavelength and radiate an outgoing electromagnetic radiationat a second wavelength; said one or more emitters producing saidincoming electromagnetic radiation such that at least a portion of saidphoto-luminescent visual element is illuminated; said first wavelengthlocated outside of the visible spectrum; said second wavelength locatedin the visible spectrum; and said emitter further characterized in thatit is located remotely from said photo-luminescent visual element.

Exemplary Embodiment 1.2 {1.1 Plus More than One Visual Element}

In a related embodiment, a display system according to an embodiment ofthe present disclosure comprises: a plurality of photo-luminescentvisual elements receiving, from one or more emitters, incomingelectromagnetic radiation at a first wavelength and radiate an outgoingelectromagnetic radiation at a second wavelength; said one or moreemitters producing said incoming electromagnetic radiation such that atleast a portion of said plurality of photo-luminescent visual elementsare illuminated; said first wavelength located outside of the visiblespectrum; said second wavelength located in the visible spectrum; andsaid emitter further characterized in that it is located remotely fromsaid photo-luminescent visual element.

Exemplary Embodiment 2.0 {Basic System 1.0 Plus a Substrate on which thePigment is Coupled, Viewing Plane is Substantially Transparent to SecondWavelength}

A display system according to an embodiment of the present disclosurecomprises: a substrate having a pigment side and a viewing side; coupledto said pigment side of said substrate a photo-luminescent pigmentreceiving from an emitter an incoming electromagnetic radiation at afirst wavelength and radiating an outgoing electromagnetic radiation ata second wavelength; said emitter producing said incomingelectromagnetic radiation such that at least a portion of saidphoto-luminescent pigment is illuminated; said first wavelength locatedoutside of the visible spectrum; said second wavelength located in thevisible spectrum; said emitter further characterized in that it islocated remotely from said photo-luminescent visual element; and, saidsubstrate at least partially transparent to said second wavelength.

Exemplary Embodiment 2.0a

The embodiment of 2.0 further characterized in that the viewing side andthe pigment side are the same side.

Exemplary Embodiment 2.1 {Basic System 2.0 Plus the Outgoing EMRadiation is Uniformly Viewable from Both Sides}

The system according to embodiment 2.0 additionally characterized inthat: the outgoing electromagnetic radiation at said second wavelengthcomprises an obverse portion passing through said substrate and areverse portion that does not pass through said substrate, and furthercharacterized in that the energy contents of said obverse portion andsaid reverse portion differ by no more than the least noticeabledifference. In some applications the least noticeable difference isabout 20% or less, in other applications it is about 10% or less, and instill other applications it is about 5% or less.

Exemplary Embodiment 2.2 {2.0 Plus Substrate is Substantially Opaque toFirst Wavelength}

The system of according to embodiment 2.0 additionally characterized inthat: said substrate is substantially opaque to said first wavelength.

Exemplary Embodiment 2.3 {2.0 Plus a Second Substrate Between theEmitter and the Pigment}

A display system according to an embodiment of the present disclosurecomprises: a first substrate having a pigment side and a viewing side;coupled to said pigment side of said first substrate a photo-luminescentpigment receiving, from an emitter, an incoming electromagneticradiation at a first wavelength and radiating an outgoingelectromagnetic radiation at a second wavelength; a second substratedisposed between said emitter and said photo-luminescent pigment suchthat at least a portion of said incoming electromagnetic radiationpasses through said second substrate; said emitter producing saidincoming electromagnetic radiation such that at least a portion of saidphoto-luminescent pigment is illuminated; said first wavelength locatedoutside of the visible spectrum; said second wavelength located in thevisible spectrum; said emitter further characterized in that it islocated remotely from said photo-luminescent pigment; said firstsubstrate and said second substrate substantially transparent to saidsecond wavelength; and, said second substrate at least partiallytransparent to said first wavelength.

Exemplary Embodiment 2.4 {System 2.3 Plus the Outgoing EM Radiation isUniformly Viewable from Both Sides}

The system according to embodiment 2.0 additionally characterized inthat: the outgoing electromagnetic radiation at said second wavelengthcomprises an obverse portion passing through said first substrate and areverse portion passing through said second substrate, and furthercharacterized in that the energy contents of said obverse portion andsaid reverse portion differ by no more than about the least noticeabledifference. In some applications the least noticeable difference isabout 20% or less, in other applications it is about 10% or less, and instill other applications it is about 5% or less.

Exemplary Embodiment 3.0 {Adding Reflection Control Features to PlanarSubstrate}

A display system according to an embodiment of the present disclosurecomprises: a photo-luminescent visual element receiving an incomingelectromagnetic radiation at a first wavelength and radiating anoutgoing electromagnetic radiation at a second wavelength; a planarsubstrate at least partially transparent at said first wavelength anddisposed between an emitter and said photo-luminescent visual element,said emitter producing polarized electromagnetic radiation at said firstwavelength and in a direction oriented to impinge upon said planarsubstrate at an angle about the angle defined by the Brewster's anglebetween air and said planar substrate; said first wavelength locatedoutside of the visible spectrum; and, said second wavelength located inthe visible spectrum.

Exemplary Embodiment 4.0 {in which the Photo-Luminescent Material isNearly Invisible Under Ordinary Light}

A photo-luminescent visual element according to an embodiment of thepresent disclosure comprises: a photo-luminescent region coupled to asubstrate, said photo-luminescent region operative to receive anincoming electromagnetic radiation at a first wavelength and radiate anoutgoing electromagnetic radiation at a second wavelength; saidphoto-luminescent region additionally characterized in that it issubstantially transparent to wavelengths in the range of 400 nanometersto 700 nanometers; and, wherein said substrate is at least partiallytransparent to said second wavelength.

Exemplary Embodiment 5.0 {Self Supporting Structure of Photo-LuminescentPigment and Transparent Binder}

A photo-luminescent visual element according to an embodiment of thepresent disclosure comprises: a photo-luminescent pigment dispersed in asubstantially rigid binder, said photo-luminescent pigment operative toreceive an incoming electromagnetic radiation at a first wavelength andradiate an outgoing electromagnetic radiation at a second wavelength;said binder further characterized in that it is at least partiallytransparent to said first wavelength and at least partially transparentto said second wavelength; said binder shaped into an object having afirst planar surface through which said incoming electromagneticradiation passes and a second planar surface through which a portion ofsaid outgoing electromagnetic radiation passes.

Exemplary Embodiment 5.1 {Self Supporting Structure of Photo-LuminescentPigment and Transparent Binder Plus Low Reflection Emitter Arrangment}

A photo-luminescent visual element according to an embodiment of thepresent disclosure comprises: a photo-luminescent pigment dispersed in arigid binder, said photo-luminescent pigment operative to receive, froman emitter, an incoming electromagnetic radiation at a first wavelengthand radiate an outgoing electromagnetic radiation at a secondwavelength; said binder further characterized in that it is at leastpartially transparent to said first wavelength and at least partiallytransparent to said second wavelength; said binder shaped into an objecthaving a first planar surface through which said incomingelectromagnetic radiation passes and a second planar surface throughwhich a portion of said outgoing electromagnetic radiation passes; saidemitter producing polarized electromagnetic radiation at said firstwavelength and in a direction oriented to impinge upon said first planarsurface at an angle about the angle defined by the Brewster's anglebetween air and said binder.

Exemplary Embodiment 6.0 {Self Supporting Structure of Photo-LuminescentPigment Fused to a Glass Viewing Plane}

A photo-luminescent visual element according to an embodiment of thepresent disclosure comprises: a planar substrate having both a viewingside and a pigment side; a photo-luminescent pigment fused on to saidpigment side, said photo-luminescent pigment operative to receive anincoming electromagnetic radiation at a first wavelength and radiate anoutgoing electromagnetic radiation at a second wavelength; said planarsubstrate further characterized in that it is at least partiallytransparent to said second wavelength; said planar substrate shaped suchthat at least a portion of said outgoing electromagnetic radiationpasses through said viewing side; the photo-luminescent visual elementfurther characterized in that: said outgoing electromagnetic radiationat said second wavelength comprises an obverse portion passing throughsaid planar substrate and a reverse portion not passing through saidplanar substrate, and further characterized in that the energy contentsof said obverse portion and said reverse portion differ from each otherby no more than about the least noticeable difference. In someapplications the least noticeable difference is about 20% or less, inother applications it is about 10% or less, and in still otherapplications it is about 5% or less.

Exemplary Embodiment 6.1 {Self Supporting Structure of Photo-LuminescentPigment Fused to a Glass Viewing Plane, Pigment is EssentiallyTransparent at Visible Wavelengths}

A photo-luminescent visual element according to an embodiment of thepresent disclosure comprises: a planar substrate having both a viewingside and a pigment side; a photo-luminescent pigment fused onto saidpigment side, said photo-luminescent pigment operative to receive anincoming electromagnetic radiation at a first wavelength and radiate anoutgoing electromagnetic radiation at a second wavelength; said planarsubstrate further characterized in that it is at least partiallytransparent to said second wavelength; said planar substrate shaped suchthat at least a portion of said outgoing electromagnetic radiationpasses through said viewing side; and said photo-luminescent pigmentadditionally characterized in that it is substantially transparent towavelengths in the range of 400 nm to 700 nm.

Exemplary Embodiment 6.1a

The embodiment of 6.1 further characterized in that the viewing side andthe pigment side are the same side.

Exemplary Embodiment 6.2 {Self Supporting Structure of Photo-LuminescentPigment Fused Between Two Glass Planes}

A photo-luminescent visual element according to an embodiment of thepresent disclosure comprises: a first planar substrate having both aviewing side and a pigment side; a photo-luminescent pigment fused ontosaid pigment side of said first planar substrate; a second planarsubstrate having both a viewing side and a pigment side; said pigmentside of said second planar substrate fused to said pigment side of saidfirst planar substrate, said photo-luminescent pigment operative toreceive an incoming electromagnetic radiation at a first wavelength andradiate an outgoing electromagnetic radiation at a second wavelength;said first planar substrate further characterized in that it is at leastpartially transparent to said second wavelength; said first planarsubstrate shaped such that at least a portion of said outgoingelectromagnetic radiation passes through said viewing side; said secondplanar substrate further characterized in that it is at least partiallytransparent to said first wavelength; said second planar substrateshaped such that at least a portion of said incoming electromagneticradiation passes through said viewing side.

Exemplary Embodiment 6.3 {Self Supporting Structure of Photo-LuminescentPigment Fused Between Two Glass Planes, Pigment being Transparent toVisible Light}

A photo-luminescent visual element according to an embodiment of thepresent disclosure comprises: a first planar substrate having both aviewing side and a pigment side; a photo-luminescent pigment fused ontosaid pigment side of said first planar substrate; a second planarsubstrate having both a viewing side and a pigment side; said pigmentside of said second planar substrate fused to said pigment side of saidfirst planar substrate, said photo-luminescent pigment operative toreceive an incoming electromagnetic radiation at a first wavelength andradiate an outgoing electromagnetic radiation at a second wavelength;said first planar substrate further characterized in that it is at leastpartially transparent to said second wavelength; said first planarsubstrate shaped such that at least a portion of said outgoingelectromagnetic radiation passes through said viewing side; said secondplanar substrate further characterized in that it is at least partiallytransparent to said first wavelength; said second planar substrateshaped such that at least a portion of said incoming electromagneticradiation passes through said viewing side; and said photo-luminescentpigment additionally characterized in that it is substantiallytransparent to wavelengths in the range of 400 nm to 700 nm.

Exemplary Embodiment 7.0 {Edge Lit Substrate in Contact with a Patternof Photo-Luminescent Pigment Regions which Collectively Create One orMore Photo-Luminescent Visual Elements when Viewed from a ViewingDistance}

A display system according to an embodiment of the present disclosurecomprises: an emitter producing an incoming electromagnetic (EM)radiation at a first wavelength outside of the visual spectrum, theemitter being optically coupled to a photo-luminescent visual element;said photo-luminescent visual element comprising: a planar substratehaving at least one edge adapted to accept said incoming EM radiation;and a plurality of photo-luminescent regions in contact with said planarsubstrate in which each photo-luminescent region receives a portion ofsaid incoming EM radiation and in which each photo-luminescent regionproduces by means of photo-luminescence an outgoing EM radiation havinga wavelength within the visible spectrum.

BRIEF DESCRIPTION OF THE DRAWINGS

These and other features, aspects, and advantages of the presentinvention will become better understood with regard to the followingdescription, appended claims, and accompanying drawings where:

FIG. 1A shows a perspective view of a photo-luminescent display systemaccording to the present disclosure. Cross section 1B is indicated onthis figure.

FIG. 1B shows a cross sectional view the photo-luminescent visualelement and an emitter corresponding to FIG. 1A.

FIG. 2A shows a perspective view of a photo-luminescent display systemaccording to another embodiment of the present disclosure. Sectionalview 2B is indicated in this figure.

FIG. 2B shows a cross sectional view the photo-luminescent visualelement and an emitter corresponding to FIG. 2A.

FIG. 3 shows a cross sectional schematic view according to anotherembodiment of the present disclosure having one or more emitters.

FIG. 4 shows a cross sectional schematic view according to anotherembodiment of the present disclosure in which a photo-luminescent visualelement has one or more photo-luminescent regions.

FIG. 5 shows a cross sectional schematic view according to anotherembodiment of the present disclosure in which a photo-luminescent visualelement has a photo-luminescent pigment between a first and a secondsubstrate.

FIG. 6 shows a cross sectional schematic view according to anotherembodiment of the present disclosure in which an emitter emits apolarized incoming EM radiation having an angle of incidence withrespect to a planar substrate.

FIG. 7 shows a cross sectional schematic view according to anotherembodiment of the present disclosure in which a photo-luminescent visualelement comprises a photo-luminescent pigment in dispersed in a rigidbinder.

FIG. 8 shows a schematic cross sectional view according to anotherembodiment of the present disclosure in which a photo-luminescent visualelement comprises a photo-luminescent pigment fused to a substrate.

FIG. 9A shows a perspective view of a photo-luminescent display systemaccording to the present disclosure. Cross section 9B and enlargement 9Care both indicated on this figure.

FIG. 9B shows a cross sectional view the photo-luminescent visualelement and an emitter corresponding to FIG. 9A.

FIG. 9C shows a enlarged view of a plurality of photo-luminescentregions in contact with a planar substrate corresponding to FIG. 9A.

LIST OF REFERENCE NUMBERS APPEARING IN THE FIGURES

-   -   2—photo-luminescent display system    -   10—photo-luminescent visual element    -   10 a, 10 b—first, second photo-luminescent visual element    -   11—photo-luminescent pigment    -   12—photo-luminescent region    -   12 a, 12 b, etc.—first, second, etc. photo-luminescent region    -   13—photo-luminescent pigment dispersed in a binder    -   20—substrate    -   20 a, 20 b—first, second substrates    -   22—binder    -   24—planar substrate    -   24 a, 24 b—first, second planar substrates    -   25—planar surface    -   25 a, 25 b—first, second planar surface    -   26—pigment side    -   27—substrate edge    -   28—viewing side    -   30—emitter    -   30 a, 30 b—first, second emitter    -   31—angle of incidence    -   32—incoming EM radiation at a first wavelength    -   32 a, 32 b—first, second incoming EM radiation    -   34—polarized incoming EM radiation at a first wavelength    -   34 a, 34 b—first, second polarized incoming EM radiation    -   40—outgoing EM radiation at a second wavelength    -   40 a, 40 b—first, second outgoing EM radiation    -   42—obverse portion of outgoing radiation    -   44—reverse portion of outgoing radiation

DESCRIPTION

Embodiments of the present disclosure provide photo-luminescent displaysystems and photo-luminescent visual elements suitable for use in suchsystems. In particular, the present disclosure describesphoto-luminescent display systems and elements that improve the abilityto create compelling, interesting, and eye-catching displays.

Photo-luminescent materials have the following useful property: theyabsorb electromagnetic (EM) energy at one wavelength and then radiate EMenergy at a second wavelength. Depending upon the specific materialused, a photo-luminescent material may absorb incoming EM radiation atone or more wavelengths and may radiate outgoing EM radiation at one ormore wavelengths. A mixture of photo-luminescent materials may absorb arange of wavelengths while radiating a range of wavelengths. Thusphoto-luminescent materials may be selected to suit a variety ofparticular applications.

Preferred photo-luminescent materials in the present disclosure absorbwavelengths in the ultraviolet (UV), below about 400 nanometers, whileradiating in the range visible to humans, from around 400 nanometers upto around 700 nanometers. Examples of inorganic photo-luminescentmaterials include alkaline earth aluminates doped with rare earths, suchas strontium aluminate, and zinc sulfide doped with copper. Many otherphoto-luminescent materials are known in the art and are able to be usedin the apparatus and systems of the present disclosure.

Embodiments of the present disclosure create one or morephoto-luminescent visual elements and illuminate those elements by meansof one or more remote emitters. Each photo-luminescent visual elementcontains one or more photo-luminescent pigments. The remote emitter oremitters provide an incoming electromagnetic radiation to thephoto-luminescent pigments at a first wavelength that is effective forbeing absorbed by the photo-luminescent pigment. After absorbing theincoming EM radiation, the pigment may then radiate a second wavelengthof light as outgoing EM radiation. In preferred embodiments, the firstwavelength is outside of the visual range of humans and the secondwavelength is within the visual range of humans. Shaping thephoto-luminescent pigment into one or more symbols, logos, letters,pictures, etc., and illuminating the pigment via one or more emitterscreates an eye-catching impression in which a display emits a glow inthe form of the shaped pigment and in which the source of illuminationis not obvious because the emitter is operating in a wavelength or rangeof wavelengths that is mostly, substantially, or entirely outside of thehuman visual range.

In some embodiments of the present disclosure, photo-luminescent pigmentmay be shaped into a thin layer that is effective for allowing theoutgoing EM radiation to be visible from all directions. The density anddeposition of the pigment layer may be controlled so that outgoing EMradiation energy is substantially uniformly distributed therebyproducing a visual impression upon the viewer that the visual article isglowing with about the same intensity when viewed from more than oneangle.

Incoming EM radiation may be absorbed by a photo-luminescent pigmentfrom a substantially unidirectional source while outgoing EM radiationis emitted omni-directionally. A thin layer or a volume of sufficientlydispersed photo-luminescent pigment will allow the incoming EM radiationto reach a substantial portion of the photo-luminescent pigment forabsorption. This improves the uniformity of the outgoing EM radiationemitted by the photo-luminescent pigment. In addition, a thin layer or avolume of sufficiently dispersed photo-luminescent pigment will allow asubstantial portion of the emitted radiation to exit thephoto-luminescent visual element without being absorbed. Thus theperception in the eye of the viewer of substantially uniform brightnessof photo-luminescent emission is improved by thinly layered or thinvolumetrically dispersed photo-luminescent pigments.

In some embodiments of the present disclosure, photo-luminescent pigmentmay be selected and applied to or otherwise incorporated into a visualelement so that the pigment is substantially transparent to visiblelight. Such a visual element would be nearly invisible when the emitteris not emitting a wavelength effective for absorption by thephoto-luminescent pigment. Upon receiving a wavelength effective forabsorption by the photo-luminescent pigment the one or more symbols,logos, letters, pictures, etc. would appear to the viewer and produce apleasing surprise and thereby very effectively convey an advertising ormarketing message.

Embodiments of the present disclosure benefit from locating the emitterremotely from the visual element, enhancing the surprise quality of thevisual effect by avoiding drawing attention to the emitter. Thephoto-luminescent visual element can stand by itself at its own locationand thereby draw the viewer's attention more effectively. Locating theemitter remotely from the visual element has other benefits. Theuniformity of power density present in the incoming EM radiation may beimproved by moving the emitter farther away from the photo-luminescentvisual element. The uniformity of the outgoing EM radiation may beimproved as a consequence of improving the uniformity of the incoming EMradiation.

In general, devices making use of UV or near UV light need to bedesigned to ensure eye safety. Various embodiments of the presentdisclosure address eye safety needs. In preferred embodiments thecumulative power and spectral output of the one or more emitters isintrinsically eye-safe. In some embodiments, an emitter may producepolarized light having an angle of incidence with respect to thesubstrate in which or on which the photo-luminescent pigment is located.When the polarized incoming EM radiation arrives at the substrate withan angle of incidence equal to about the Brewster's angle then verylittle reflection may be produced. This has the effect of controllingreflections to a very substantial degree at the same time that theincoming EM radiation is transmitted into the substrate with highefficiency. It is noted that the Brewster's angle in these embodimentsis given by a formula involving the index of refraction of the substrateand that of air according to the equation: Brewster's Angle=arctangent(refractive index of substrate/refractive index of air).

Further UV control may be obtained in other embodiments. In anembodiment where an emitter illuminates a photo-luminescent visualelement from one side while the visual element is being viewed from theopposite side, a substrate that is at least partially transparent tovisible light and at least partially opaque to UV may be interposedbetween the emitter and the viewer to intercept unwanted UV on its wayto the viewer.

Embodiments of the present disclosure describe a number of ways in whicha photo-luminescent pigment may be coupled with or combined with asubstrate suitable for the variety of applications contemplated: aphoto-luminescent pigment may be combined with a binder or adhesive forsurface application to a suitable transparent or translucent substrate;photo-luminescent pigments having sufficiently high temperaturestability may be infused, fused, sintered, or even encapsulated on or incompatible plastic, glass, or glass-like substrates; pigments compatiblewith plastics, rubber compounds, urethanes, epoxies, may be dispersed,layered, or mixed into such binders thereby creating photo-luminescentcomposite materials. All of the foregoing methods may be used to createrigid photo-luminescent visual elements capable of supporting their ownweight.

Turning now to FIG. 1A, an embodiment of a photo-luminescent displaysystem 2 according to the present disclosure is shown comprising:photo-luminescent visual element 10 receiving, from a remotely locatedemitter 30, incoming electromagnetic (EM) radiation 32 at a firstwavelength; the photo-luminescent visual element radiating outgoingelectromagnetic radiation 40 at a second wavelength in response toreceiving said incoming EM radiation; emitter 30 producing said incomingEM radiation such that at least a portion of said photo-luminescentvisual element 10 is illuminated; said first wavelength located outsideof the visible spectrum; said second wavelength located in the visiblespectrum; and said emitter further characterized in that it is locatedremotely from said photo-luminescent visual element. The outgoing EMradiation may comprise an obverse portion 42 and a reverse portion 44,both portions emanating from the photo-luminescent visual element andtraveling in different directions. The visual content ofphoto-luminescent visual element 10 can be viewed from both sides of theelement.

Shown in FIG. 1B is a cross section of the photo-luminescent visualelement and emitter of FIG. 1A. An embodiment of a photo-luminescentvisual element 10 is shown comprising a photo-luminescent pigment 11coupled to a substrate 20. Emitter 30 produces incoming EM radiation 32at a first wavelength, at least a portion of which is absorbed by saidphoto-luminescent pigment 11 and then radiated as an outgoing EMradiation 40 at a second wavelength. An obverse portion 42 of outgoingEM radiation 40 passes through substrate 20, while a reverse portion 44of outgoing EM radiation 40 does not pass through the substrate. Inpreferred embodiments, said first wavelength is outside the visiblespectrum while said second wavelength is within the visible spectrum.Preferred embodiments of photo-luminescent visual element 10 usesubstrate materials that are substantially transparent to said secondwavelength, such as glass or acrylic. Effectively thin or dispersedapplications of photo-luminescent pigment 11 create the benefit that theenergy contents of said obverse portion and said reverse portion differfrom each other by no more than about 30%. This produces an impressionof nearly equal radiance of obverse and reverse portions in the eye ofthe viewer and may be highly desirable in some applications.

The difference between said obverse portion and said reverse portion mayalso be characterized in terms of a least noticeable difference inintensity as judged by the human eye. The least noticeable differencemay be defined in a ratio-metric way as the quotient (difference inintensity)/(absolute intensity of the obverse portion). Depending on theindividual viewing the photo-luminescent visual element, the leastnoticeable difference between the obverse portion and the reverseportion may be about 20% or less, in other applications it may be about10% or less, and in still other applications it may be about 5% or less.

FIG. 2A shows an embodiment similar to that shown in FIG. 1A, differingin the placement of the remote emitter. FIG. 1A and FIG. 2A takentogether show that embodiments of the present disclosure comprisephoto-luminescent visual elements that can be illuminated at a firstwavelength by an emitter remotely positioned in any one of a variety ofplacements and that the subsequent photo-luminescent visual elements canthen be viewed at a second wavelength from many different angles.

Shown in FIG. 2B is a cross section of the photo-luminescent visualelement and emitter of FIG. 2A. An embodiment of a photo-luminescentvisual element 10 is shown comprising a photo-luminescent pigment 11coupled to a substrate 20. Emitter 30 produces incoming EM radiation 32at a first wavelength, at least a portion of which is absorbed by saidphoto-luminescent pigment 11 and then radiated as an outgoing EMradiation 40 at a second wavelength. An obverse portion 42 of outgoingEM radiation 40 passes through substrate 20, while a reverse portion 44of outgoing EM radiation 40 does not pass through the substrate. Inpreferred embodiments, first wavelength is outside the visible spectrumwhile the second wavelength is with the visible spectrum. Preferredembodiments of photo-luminescent visual element 10 use substratematerials that are substantially transparent to said second wavelength,such as glass or acrylic. Effectively thin or dispersed applications ofphoto-luminescent pigment 11 create the benefit that the energy contentsof said obverse portion and said reverse portion differ from each otherby no more than about the least noticeable difference. This produces animpression of nearly equal radiance of obverse and reverse portions inthe eye of the viewer.

Turning now to FIG. 3, shown is a schematic cross section view accordingto another embodiment of the present disclosure having more than oneemitter. An embodiment of a photo-luminescent display system 2 accordingto the present disclosure is shown comprising: a remotely located firstemitter 30 a radiating a first incoming electromagnetic (EM) radiation32 a at a first wavelength; a remotely located second emitter 30 bradiating a second incoming EM radiation 32 b at said first wavelength;a photo-luminescent visual element 10 receiving at least a portion ofsaid first incoming EM radiation 32 a or at least a portion of saidsecond incoming EM radiation 32 b, the photo-luminescent visual elementradiating outgoing EM radiation 40 at a second wavelength in response toreceiving either of said first incoming EM radiation 32 a or said secondincoming EM radiation 32 b; first emitter 30 a producing said firstincoming EM radiation 32 a such that at least a portion of saidphoto-luminescent visual element 10 is illuminated; second emitter 30 bproducing said second incoming EM radiation 32 b such that at least aportion of said photo-luminescent visual element 10 is illuminated; saidfirst wavelength located outside of the visible spectrum; said secondwavelength located within the visible spectrum; said first emitter 30 afurther characterized in that it is located remotely from saidphoto-luminescent visual element; said second emitter 30 b furthercharacterized in that it is located remotely from said photo-luminescentvisual element. The outgoing EM radiation may comprise an obverseportion and a reverse portion, both portions emanating from thephoto-luminescent visual element and traveling in different directions.

Turning now to FIG. 4, shown is a cross sectional schematic viewaccording to another embodiment of the present disclosure in which aphoto-luminescent visual element has one or more photo-luminescentregions. An embodiment of a photo-luminescent display system 2 accordingto the present disclosure is shown comprising: a remotely locatedemitter 30 producing an incoming EM radiation 32 at a first wavelengthdirected towards a photo-luminescent visual element 10; saidphoto-luminescent visual element 10 comprising: a firstphoto-luminescent region 12 a coupled to a substrate 20; a secondphoto-luminescent region 12 b coupled to said substrate; wherein saidfirst photo-luminescent region 12 a receives a portion of incoming EMradiation 32 and produces first outgoing EM radiation 40 a at a secondwavelength; and wherein said second photo-luminescent region 12 breceives a portion of incoming EM radiation 32 and produces a secondoutgoing EM radiation 40 b at a third wavelength. Said second and saidthird wavelengths may be the same or different wavelengths, both withinthe human visual spectrum.

In consideration of the embodiments of FIG. 3 and FIG. 4, it is withinthe spirit and scope of the present disclosure to create an embodimenthaving multiple emitters radiating towards multiple photo-luminescentelements. Furthermore, different photo-luminescent regions may produceoutgoing EM radiation at different wavelengths thereby enabling displaysystems with a spectrum of color characteristics. A plurality ofphoto-luminescent regions may be used in which a plurality ofphoto-luminescent pigments radiate at a plurality of wavelengths. Theplurality of photo-luminescent regions may also vary in size, therebyproviding a wide range of visual effects.

Shown now in FIG. 5 is a system 2 comprising a remotely located emitter30 producing an incoming EM radiation 32 at a first wavelength anddirected toward a photo-luminescent element 10, said photo-luminescentelement 10 comprising: a photo-luminescent pigment 11 disposed between afirst substrate 20 a and a second substrate 20 b; the photo-luminescentpigment operative to radiate an outgoing EM radiation 40 at a secondwavelength; said outgoing EM radiation comprising both an obverseportion 42 passing through first substrate 20 a and a reverse portion 44passing through second substrate 20 b.

The system of FIG. 5 has a number of advantages. Some photo-luminescentpigments may be sensitive to environmental conditions such astemperature, humidity, oxygen, etc. By encapsulating photo-luminescentpigment between two substrates the impact of environmental factors onthe operational characteristics and lifetime on the photo-luminescentvisual element may be reduced.

Further advantages may be realized from the embodiment of FIG. 5. Thesubstrate that incoming EM radiation at the first wavelength passesthrough on its way to the photo-luminescent pigment may be selected tosubstantially pass the first wavelength while the other substrate may beselected to substantially block the first wavelength. Such aconfiguration has the advantage of blocking most of the energy at thefirst wavelength that would otherwise pass through the other substrate.In embodiments where the first wavelength is in the UV portion of thespectrum, it may be beneficial to block the transmission through theother substrate of at least a portion of the UV light that was notabsorbed by the photo-luminescent pigment. Use of a UV blockingsubstrate between the photo-luminescent pigment and a viewer may enhancethe eye-safety of the system by blocking a portion of the unabsorbedincoming EM radiation that is in the UV band.

With continuing reference to FIG. 5, a sufficiently thin or dispersedlayer of photo-luminescent pigment may be used such that the layerappears substantially transparent to wavelengths in the visiblespectrum. When exposed to incoming EM radiation at the first wavelengthsuch a layer will radiate at the second wavelength and hence becomevisible. A variety of eye-catching and useful transparent and semitransparent effects may be produced.

FIG. 6 shows an embodiment similar to the system of FIG. 5. Theembodiment of FIG. 6 is further characterized in that second substrate20 b has a planar surface 25 disposed to receive, at an angle ofincidence 31, a polarized incoming EM radiation 34 at a firstwavelength. Remotely located emitter 30 produces said polarized incomingEM radiation 34, directing it towards said planar surface 25 at saidangle of incidence 31. In preferred embodiments, the direction ofpolarization and the angle of incidence may be coordinated such thatsaid incoming EM radiation 34 arrives at said planar surface 25 at aboutthe Brewster's angle and produces substantially no reflection of thefirst wavelength from planar surface 25. When polarized and directed inthe described way, reflections from said planar surface may beminimized. Such an arrangement may be used to enhance eye-safety bycontrolling reflections of the first wavelength from said planarsurface.

Turning now to FIG. 7, shown is a cross sectional schematic viewaccording to another embodiment of the present disclosure in which aphoto-luminescent visual element 10 comprises a photo-luminescentpigment dispersed in a binder 13, the composite being sufficiently rigidto maintain its shape under the force of gravity. Emitter 30 produces aincoming EM radiation 34 at a first wavelength that is directed towardsaid photo-luminescent pigment dispersed in a binder 13 with an angle ofincidence 31. The photo-luminescent pigment produces an outgoing EMradiation 40 at a second wavelength, transmitting a reverse portionthrough a first planar surface 25 a and an obverse portion through asecond planar surface 25 b. In preferred embodiments, the direction ofpolarization and the angle of incidence may be coordinated such thatsaid incoming EM radiation 34 arrives at said first planar surface 25 aat about the Brewster's angle and produces substantially no reflectionof the first wavelength from first planar surface 25 a.

Depending upon the effect desired, the photo-luminescent pigment in theembodiment of FIG. 7 may be dispersed throughout the majority of thebinder or it may be dispersed through only a portion of the binder. Thebinder is at least partially transparent to the first wavelength and atleast partially transparent to the second wavelength.

With reference now to FIG. 8, shown is another embodiment of aphoto-luminescent display system comprising: an emitter 30 producing anincoming EM radiation 34 directed toward a photo-luminescent visualelement 10 comprising: a planar substrate 24 having both a pigment side26 and a viewing side 28; and, a photo-luminescent pigment 11 fused tosaid pigment side. Photo-luminescent pigment 11 may be a material chosento survive elevated temperatures required for fusing it to the pigmentside of the substrate. Substrate materials may include glass andacrylic.

FIG. 9A shows a perspective view of another photo-luminescent displaysystem according to the present disclosure. A photo-luminescent displaysystem 2 according to an embodiment of the present disclosure comprises:an emitter 30 producing an incoming electromagnetic (EM) radiation 32 ata first wavelength outside of the visual spectrum, emitter 30 beingoptically coupled to a photo-luminescent visual element 10.Photo-luminescent visual element 10 is shown comprising: a planarsubstrate 24 having at least one substrate edge 27 adapted to acceptsaid incoming EM radiation 32. Photo-luminescent visual element 10produces an outgoing EM radiation 40 having an obverse portion 42 and areverse portion 44.

More detail is visible in cross sectional view FIG. 9B, which showsphoto-luminescent visual element 10 comprising a plurality ofphoto-luminescent regions 12 a, 12 b, 12 c, 12 d, and 12 e in directcontact with said planar substrate 24 in which each photo-luminescentregion receives a portion of said incoming EM radiation 32 and in whicheach photo-luminescent region produces by means of photo-luminescence anoutgoing EM radiation 40 having a wavelength within the visiblespectrum. Incoming EM radiation 32 is distributed throughout planarsubstrate 24 by means of the optical phenomenon of total internalreflection, mainly exiting the planar substrate at the locations indirect contact with any of the plurality of photo-luminescent regions.Each photo-luminescent region thereby receives a portion of incoming EMradiation 32 and then emits outgoing EM radiation at another wavelengthby means of photo-luminescence.

FIG. 9C shows an enlarged view, corresponding to FIG. 9A, of a pluralityof photo-luminescent regions 12 a, 12 b, 12 c, 12 d, and 12 e in contactwith planar substrate 24. It is noted that many or few photo-luminescentregions may be used, depending on the subject matter displayed.Furthermore the plurality of photo-luminescent regions may vary in size,position, and composition of photo-luminescent pigment such thatdifferent colors and intensities may be produced. In preferredembodiments the size and density of photo-luminescent regions may varyin a predetermined way to create an impression of nearly uniformbrightness across the entire photo-luminescent visual element. Due tothe logarithmic sensitivity of the human eye, brightness variations ofabout less than 20% may appear to be nearly uniformly bright. In otherpreferred embodiments, the geometry and intensity of the emissionpattern produced by the emitter may be taken into account when designinga pattern of photo-luminescent regions, thereby creating desirablevisual properties for the entire system. In other embodiments,brightness variations of about 10% or less appear to uniformly bright,and in still other embodiments brightness variations of about 5% or lessappear to uniformly bright.

Although the present invention has been described in considerable detailwith reference to certain preferred versions thereof, other versions arepossible. It may be desirable to combine features shown in variousembodiments into a single embodiment. A different number andconfiguration of features may be used to construct embodiments ofphoto-luminescent display systems and photo-luminescent visual elementsthat are entirely within the spirit and scope of the present disclosure.Therefor, the spirit and scope of the appended claims should not belimited to the description of the preferred versions contained herein.

Any element in a claim that does not explicitly state “means for”performing a specified function, or “step for” performing a specificfunction, is not to be interpreted as a “means” or “step” clause asspecified in 35 U.S.C. Section 112, Paragraph 6. In particular, the useof “step of” in the claims herein is not intended to invoke theprovisions of 35 U.S.C. Section 112, Paragraph 6.

The invention claimed is:
 1. A photo-luminescent visual elementcomprising: a) a photo-luminescent pigment coupled to a planarsubstrate, said photo-luminescent pigment operative to receive incomingelectromagnetic radiation at a first wavelength and, in response, emitan outgoing electromagnetic radiation at a second wavelength that iswithin the human visible spectrum; b) a second photo-luminescent pigmentcoupled to said planar substrate, said second photo-luminescent pigmentoperative to receive incoming electromagnetic radiation at said firstwavelength and, in response, emit an outgoing electromagnetic radiationat a third wavelength that is within the human visible spectrum; c) athird photo-luminescent pigment coupled to said planar substrate, saidthird photo-luminescent pigment operative to receive incomingelectromagnetic radiation at said first wavelength and, in response,emit an outgoing electromagnetic radiation at a fourth wavelength thatis within the human visible spectrum; d) said planar substrate at leastpartially transparent to each of: said second wavelength; said thirdwavelength; and, said fourth wavelength; e) further characterized inthat the outgoing electromagnetic radiation at said second wavelengthcomprises both an obverse portion and a reverse portion, the brightnessof said obverse portion differing from the brightness of said reverseportion by no more than about 30% or less.
 2. The photo-luminescentvisual element of claim 1 further characterized in that the firstwavelength is smaller than about 400 nanometers.
 3. Thephoto-luminescent visual element of claim 1 further characterized inthat the second wavelength is greater than said first wavelength andless than about 700 nanometers.
 4. The photo-luminescent visual elementof claim 1 further characterized in that each of the second wavelengthand the third wavelength are greater than said first wavelength and lessthan about 700 nanometers.
 5. The photo-luminescent visual element ofclaim 1 further characterized in that each of the second wavelength, thethird wavelength, and the fourth wavelength are greater than said firstwavelength and less than about 700 nanometers.
 6. The photo-luminescentvisual element of claim 1 further characterized in that the first, thesecond, and the third photo-luminescent pigments are arranged on saidplanar substrate in a plurality of photo-luminescent pigment regions. 7.The photo-luminescent visual element of claim 6 further characterized inthat a portion of said plurality of photo-luminescent pigment regionsare non-overlapping.
 8. A photo-luminescent visual element comprising:a) a planar substrate having at least one substrate edge adapted toaccept an incoming electromagnetic radiation at a first wavelength; saidplanar substrate configured to retain a portion of said incomingelectromagnetic radiation by means of total internal reflection withinsaid planar substrate; b) a plurality of photo-luminescent regions indirect contact with said planar substrate; each photo-luminescent regionreceiving a portion of said incoming electromagnetic radiation; c) afirst portion of said photo-luminescent regions producing by means ofphoto-luminescence an outgoing electromagnetic radiation having a secondwavelength within the human visible spectrum; d) a second portion ofsaid photo-luminescent regions producing by means of photo-luminescencean outgoing electromagnetic radiation having a third wavelength withinthe human visible spectrum; e) a third portion of said photo-luminescentregions producing by means of photo-luminescence an outgoingelectromagnetic radiation having a fourth wavelength within the humanvisible spectrum; f) said outgoing electromagnetic radiation at saidsecond wavelength comprising an obverse portion and a reverse portion,each emitted away from opposites sides of said planar substrate; g) thephoto-luminescent visual element further characterized in that thebrightness at said second wavelength of said obverse portion and saidreverse portion differ by no more than about 30% or less.
 9. Thephoto-luminescent visual element of claim 8 further characterized inthat the first wavelength is smaller than about 400 nanometers.
 10. Thephoto-luminescent visual element of claim 8 further characterized inthat the second wavelength is greater than said first wavelength andless than about 700 nanometers.
 11. The photo-luminescent visual elementof claim 8 further characterized in that each of the second wavelengthand the third wavelength are greater than said first wavelength and lessthan about 700 nanometers.
 12. The photo-luminescent visual element ofclaim 8 further characterized in that each of the second wavelength, thethird wavelength, and the fourth wavelength are greater than said firstwavelength and less than about 700 nanometers.
 13. The photo-luminescentvisual element of claim 8 further characterized in that the first, thesecond, and the third photo-luminescent pigments are arranged on saidplanar substrate in a plurality of photo-luminescent pigment regions.14. The photo-luminescent visual element of claim 13 furthercharacterized in that a portion of said plurality of photo-luminescentpigment regions are non-overlapping.
 15. A photo-luminescent visualelement comprising: a) a planar substrate having both a viewing side anda pigment side; b) a first photo-luminescent pigment coupled to saidplanar substrate proximate to said pigment side; said firstphoto-luminescent pigment operative to receive an incomingelectromagnetic radiation at a first wavelength and, in response, emitan outgoing electromagnetic radiation at a second wavelength that iswithin the human visible spectrum; c) a second photo-luminescent pigmentcoupled to said planar substrate proximate to said pigment side, saidsecond photo-luminescent pigment operative to receive incomingelectromagnetic radiation at said first wavelength and, in response,emit an outgoing electromagnetic radiation at a third wavelength that iswithin the human visible spectrum; d) a third photo-luminescent pigmentcoupled to said planar substrate proximate to said pigment side, saidthird photo-luminescent pigment operative to receive incomingelectromagnetic radiation at said first wavelength and, in response,emit an outgoing electromagnetic radiation at a fourth wavelength thatis within the human visible spectrum; e) said planar substrate shapedsuch that at least a portion of said outgoing electromagnetic radiationpasses through said viewing side; f) said planar substrate furthercharacterized in that it is substantially transparent to said secondwavelength; the planar substrate further characterized in that it is, atleast, partially opaque to said first wavelength; g) said firstwavelength further characterized in that it is smaller than about 400nanometers; h) said second wavelength further characterized in that itis greater than said first wavelength and less than about 700nanometers.
 16. The photo-luminescent visual element of claim 15 furthercharacterized in that the third wavelength is greater than said firstwavelength and less than about 700 nanometers.
 17. The photo-luminescentvisual element of claim 15 further characterized in that each of thethird wavelength and the fourth wavelength are greater than said firstwavelength and less than about 700 nanometers.